DE60017412T2 - SEALED WAVELENGTH MULTIPLEXER HIGH ISOLATION WITH POLARIZING RADIANT, NONLINEAR INTERFEROMETER AND DOUBLE BREAKING PLATES - Google Patents

Description

AREA OF INVENTION

The The present invention relates to fiber optic networks, and more particularly Fiber optic multiplexers of dense wavelengths.

BACKGROUND THE INVENTION

WO-A-99/08403 describes a wavelength division multiplexer for use in a communication network with optical cross Connect. An optical signal is transmitted through a birefringent plate into a polarization beam splitter and then into a wavelength filter initiated. The polarization beam splitter separates the optical channels The optical signal based on the polarity of the same and passes them to different exits, to which they pass through the wavelength filter transferred either or reflected.

JP-A-05 316052 discloses a polarized wave diversity optical receiver in which Polarizing beam splitter is used in conjunction with at least a birefringent plate to receive a received optical signal to separate into a variety of optical channels based on of polarity the optical channels.

US-A-4 558 950 describes a method and an apparatus for an interferometric Distance and direction measurement. This document discloses the use an interferometer arrangement for such a measurement.

US-A-5 504 619 discloses a light deflecting unit for an optical device for scanning an inner surface a cylinder with a ray of light. The arrangement comprises at least a birefringent plate and a polarization beam splitter, which optionally light in different directions accordingly the polarization of the same forwards.

Optics Letter, Optical Society of America, Washington, US, vol. 23, no. 14, 15 July 1998, pages 1099-1102, Dingel BB et al., Entitled "Multifunction Optical Filter with a Michelson-Gires-Tournois Interferometer for Wavelength-Division-Multiplexed Network System Applications "revealed a Michelson interferometer arrangement in an optical filter for optical Multi-wavelength communication systems and high-density wavelength-multiplexed network systems.

Fiberoptic Networks are for the data transmission increasingly popular, because of their skills for one high speed and high data capacity. Multiple wavelengths can be over the same transmit optical fiber become. This entirety of the several combined wavelengths comprises a single rendered Signal. A critical feature of a fiber optic network is the separation of the optical signal into its partial wavelengths or "channels", typically by means of a wavelength multiplexer. This separation must take place for the exchange of wavelengths between Signals on "loops" within the network, which occur. The exchange takes place at connection points or at points where two or more loops are made for the purpose of Exchanging wavelengths to cut.

systems for adding / removing (add / drop systems) are at the connection points for the management of the channel exchanges exists. The exchange of Data signals involve the replacement of related wavelengths two different loops within an optical network. In other words, each signal takes a channel in the direction of other loop out while it simultaneously adds the matching channel from the other loop.

The 1 represents a simplified optical network 100 dar. A fiber optic network 100 can a main loop 150 comprising primary locations, such as San Francisco and New York. Between these primary sites is a local loop 110 , which at the connection point 140 with the loop 150 connected is. Thus, if the local loop 110 Sacramento is multiplexed in San Francisco wavelengths into an optical signal that will migrate from San Francisco to the juncture point 140 Channels will be added (add) and dropped (dropped) with the signal from Sacramento, and the new signal will continue to travel to New York. Within the loop 110 would transmit optical signals to different locations within that loop, serving the space around Sacramento. Local receivers (not shown) would be at different points within the local loop 110 to convert the optical signals into the electrical signals in the appropriate protocol format.

The separation of an optical signal into its subchannels is typically performed by a dense wavelength divison multiplexer. The 2 introduces add / drop systems 200 and 210 (Adding and subtracting systems) with dense wavelength multiplexers 220 and 230 dar. An optical signal from the loop 110 (8 ₁ - 8 _n ) joins his add / drop system 200 at the node A ( 240 ) one. The signal is fed into its component channels through the dense wavelength multiplexer 220 separated. Each channel will then be in its own way 250-1 to 250-n output. For example, 8 would be ₁ along the way 250-1 wander, 8 ₂ would be along the way 250-2 wander, etc. In the same way, the signal exits the loop 150 (8 ₁ '- 8 _n ') in his add / drop system 210 via the node C ( 270 ) one. The signal then enters its subchannels through the wavelength division multiplexer 230 separated. Each channel will then go its own way 280-1 to 280-n output. For example, 8 would be ₁ 'along the way 280-1 wander, 8 ₂ 'would be along the way 280-2 hiking, etc.

For example, when executing an add / drop function, 8 ₁ gets out of the way 250-1 to the way 280-1 transfer. It will loop with the other channels 150 through the dense wavelength multiplexer 230 combined into a single new optical signal. The new signal is then sent via node D ( 290 ) to the loop 150 recycled. At the same time 8 ₁ 'gets out of the way 280-1 to the way 250-1 transfer. It will loop with the other channels 110 through the dense wavelength multiplexer 220 combined into a single optical signal. This new signal is then sent via node B ( 260 ) to the loop 110 recycled. In this way is from the reference system of the node 110 from the channel 8 _{1 of} its own signal in the direction of the loop 150 taken out (dropped) while the channel 8 ₁ 'of the signal from the loop 150 is added to form part of its new signal. The opposite is true for the frame of reference of the loop 150 , This is the add / drop function.

conventional Methods, which of wavelength division multiplexers used in separating an optical signal into its subchannels include the use of filters and fiber gratings as separators. A "separator" is when this one Expression used in this description is an integrated Collection of optical components that function as a unit, which one or more channels separates from an optical signal. Filters allow a destination channel passes through while all other channels returned become. Fiber grids are designed to reflect a channel while all other channels pass. Both filters and fiber grids are in the art Well known and therefore not present in greater detail described.

A problem with conventional isolation devices is the accuracy required of a device for transmitting a signal into an optical fiber. A signal entering a wavelength division multiplexer must match a set of very narrow passbands (passbands). The 3 shows an example of a spectral curve 310 which is composed of a plurality of channels when entering a dense wavelength division multiplexer. The passbands 320 the channels are very narrow. Ideally, the curve would be a square wave. A narrow pass band is problematic because, due to the physical barriers and temperature sensitivity of laser devices as the signal source, they never emit light exactly at the center wavelength of an optical filter. The difference between the actual wavelength and the wavelength in the middle of the passband is called "offset." The amount of offset or changes in the offset ("drift") should ideally not be greater than the width of the passbands. Otherwise, the crosstalk between the channels would be too large. Crosstalk occurs when a channel or part of a channel appears as a noise on a channel adjacent to it. Because the signals resulting from the configurations of conventional wavelength division multiplexers have narrow passbands, the devices of the signal source ("transmitter"), such as lasers or the like, must have high accuracy such that skew or drift affects the width of the It is difficult to achieve this high precision, high precision signal transmitting devices are available but they are very expensive, and the signal transmitting devices must be individually aligned with each separator, which is very time consuming Passbands of conventional separators, such as conventional bandpass filters, have rounded shapes, and concatenating multiple such filters in series inevitably reduces the overall widths of the passbands and increases the insertion losses of the filter assemblies removing / destroying energy at the edges of the overlapping individual passbands.

A improved separation device according to the state the technique of using a polarization beam splitter and a not used linear interferometer is in the parallel pending American Patent Application entitled "Non-Linear Interferometer for Fiber Optic Wavelength Division Multiplexer Utilizing a Phase Differential Method of Wavelength Separation ", with the application number 09/247 253, filed on February 10, 1999.

The 4 to 6 illustrate a separator disclosed in U.S. Patent Application Serial No. 09 / 247,253. This separator 1000 separates the signal into two sets of channels. The 4 Fig. 10 illustrates a top view of a preferred embodiment of a separator 1000 dar. The separator 1000 around holds an optical fiber 1010 for inputting an optical signal and optical fibers 1020 and 1030 for outputting optical signals. If the signal is the optical fiber 1010 leaves, it breaks apart. A lens 1050 directs the signal in parallel and directs it in the direction of a beam splitter 1070 which decomposes the signal based on its polarity. This decomposition takes place in one plane 1075 of the beam splitter 1070 instead of. The component (p component) of the input signal, which is within the plane, determined by the direction of movement of the input signal and a line perpendicular to the connection plane 1075 is defined, polarized, passes through the beam splitter 1070 in the direction of an interferometer 800B , The component (s component) of the input signal, which is parallel to the connection plane 1075 is polarized, is in the direction of an interferometer 800A reflected. The interferometer 800A and 800B introduce phase differences between the even and odd channels of the signals.

The 5 represents the path of the light of the odd channels as it passes through the separator 1000 with the interferometers 800A and 800B the invention of the related art field moves. The light of the odd channels moves to the polarization beam splitter 1070 from the input fiber 1010 , The light from each channel has an s-polarity component (E _s ) 1110 and a p-polarity component (E _p ) 1220 on. The E _s and E _p signals can each be in E _o and E _e components respectively parallel to the main beam directions of the birefringent elements in the interferometers 800A and 800B be disassembled. These components are well known in the art and will not be further described here. The vector E _p 1220 is in the components E _po 1230 and E _pe 1240 decomposed, whereas the vector E _s 1210 into the components E _{like that} 1250 and E _se 1260 is decomposed. The decomposition is in the 5 for each of the component vectors of the signal polarization E _s and E _p , for both, before their entry into and after their exit from the interferometers 800A and 800B , The signal E _p 1220 moves to the interferometer 800B while the signal E _s 1210 to the interferometer 800A emotional. Both sets of signals are transmitted through their interferometer 800A and 800B reflected, without a phase shift difference between E _so 1250 and E _se 1260 (or between E _po 1230 and E _pe 1240 ). Thus, both move, the signal E _p 1220 and the signal E _s 1210 , back to the polarization beam splitter 1070 without a change in orientation. These signals then move back through the polarization beam splitter 1070 to the output fiber (output fiber) 1020 ,

The 6 represents the path of the straight channels as they pass through the separator 1000 with the interferometers 800A and 800B move the present invention. As with the odd channels, the light of the even channels moves to the polarization beam splitter 1070 from the input fiber 1010 , The light from each channel has an s-polarity component (E _s ) 1210 and a p-polarity component (E _p ) 1320 on. As with the odd channels, the E _s and E _p signals can each be in E _o and E _e components parallel to the main beam direction of the birefringent elements in each of the interferometer 800A and 800B be disassembled. The vector E _p 1320 is in the components E _po 1330 and E _pe 1340 decomposed, whereas the vector E _s 1310 into the components E _{like that} 1350 and E _se 1360 is decomposed. This decomposition is in the 6 for the polarization plane of the light from each of the signal vectors E _s and E _p , for both, before their entry respectively into and after their exit from the interferometers 800A and 800B , The signal E _p 1320 moves to the interferometer 800B while the signal E _s 1310 to the interferometer 800A emotional. For the straight channels lead the interferometers 800A and 800B a phase difference π each between E _po 1330 and E _pe 1340 and also between E _{like that} 1350 and E _se 1360 one. This phase difference causes an effective π / 2 rotation of each of the signals 1310 and 1320 whereby they are each converted from E _s to E _p and from E _p to E _s . If both of these signals are through the beam splitter again 1070 move, this rotation causes them to become the output fiber (output fiber) 1030 move. Thus, in this way, the output fiber includes 1020 the odd channels, whereas the output fiber 1030 includes the even channels.

This separator has advantages over conventional separator in terms of increased width and flatness of the pass bands and the insulating bands and a greater ease of alignment. Although this separator 1000 useful for their stated purposes, it may in some cases by the characteristics of the polarization beam splitter used 1070 be limited. A perfect polarization beam splitter will separate an incident non-polarized light beam into component light beams that are polarized in two planes, with a mutual perpendicular polarization orientation, such that each component beam 100 Percent of the light of one polarization orientation and none of the light of the other orientation. However, in real beam splitters, which can never be perfect, there is always a small amount of leakage of light rays having a polarization orientation into the transmission path which is nominally composed only of light having the other polarization orientation. Because of this leakage, there will be an imperfect isolation of one set of signals from another in the separator 1000 give.

Accordingly There is a need for a separation mechanism that does it for a wavelength division multiplexer would allow a greater tolerance for one Wavelength offset and drift and a greater simplicity to exhibit in the alignment, as in conventional separators realized, as well as a greater degree of isolation between two records of separate channels. The present invention relates to such a need.

SUMMARY OF THE INVENTION

The The present invention provides a dense wavelength multiplexer (Multiplexer dense wavelength) for separating an optical signal into optical channels. she comprises at least one birefringent plate and a polarization beam splitter, which optically coupled to the at least one birefringent plate is, the polarization beam splitter and the at least one birefringent Plate for separating one or more of the plurality of optical Channels through Initiating a phase difference between at least two of the plurality the optical channels, wherein the separating is based on the polarity of the plurality of optical channels based. In a preferred embodiment, the mechanism includes separating birefringent wedge plates, a polarization beam splitter and two non-linear interferometers, with the birefringent ones Wedge plates between the polarization beam splitter and the input and exit routes are arranged. The present invention provides easier alignment and greater tolerance for drifts to disposal, due to the enlargement of the Width of the passbands, and further provides improved separation of channels relative to other wavelength division multiplexers, which polarization beam splitters use. she can also be easily modified to add / drop function to afford if they have channels separates. The materials that are required to the multiplexer dense wavelength in agreement to produce and implement with the present invention, are readily available. The present invention thus requires no special or expensive materials or processes. It is thus inexpensive.

SHORT DESCRIPTION THE DRAWINGS

The 1 is an illustration of a simplified optical network.

The 2 is an illustration of a conventional add / drop system and wavelength division multiplexers.

The 3 Figure 12 is a graph of two exemplary spectral curves, each composed of multiple channels, each entering a conventional wavelength division multiplexer and a dense wavelength division multiplexer in accordance with the present invention.

The 4 FIG. 12 is an illustration of a separator employing a polarization beam splitter and non-linear interferometers. FIG.

The 5 is a representation of odd channels as they pass through the separator 4 move.

The 6 is a representation of straight channels as they pass through the separator 4 move.

The 7 Figure 11 is a top view of a preferred embodiment of a separator in accordance with the present invention.

The 8th Fig. 12 is an illustration of a preferable embodiment of a non-linear interferometer used with the separator of the present invention.

The 9 Fig. 10 is an illustration of an optical path through the preferred embodiment of the separator of light signals and subsignals input from the first input fiber and corresponding paths of light signals from odd channels in accordance with the present invention.

The 10 Fig. 13 is an illustration of the optical paths by the preferable embodiment of the separator of light signals and subsignals input from the first input fiber and corresponding to the paths of light signals from even channels in accordance with the present invention.

The 11 FIG. 11 is a flow chart illustrating a preferred embodiment of a method of separating an optical signal in accordance with the present invention.

The 12 Fig. 13 is an illustration of optical paths through the preferred embodiment of the optical signal separator and sub-signals introduced by the second input fiber and corresponding odd channels in accordance with the present invention.

The 13 Fig. 12 is an illustration of the optical paths through the preferred embodiment of light signals and subsignals input from the second input fiber and corresponding to the even channels in accordance with the present invention.

The 14 Figure 3 is a functional routing diagram for the disconnect device of the present invention illustrating its operation as a 2x2 device.

The 15 Figure 10 is a simple block diagram of a wavelength division multiplexer with a cascade configuration having multiple parallel stages of separators in accordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The The present invention relates to an improvement in the Separation mechanism used in dense wavelength division multiplexers should. The following description is provided to one of ordinary skill in the art to be able to carry out and use the invention, and it is presented in the context of a patent application and its requirements. Various modifications will be made to the preferred embodiment for the Be easily recognized by the person skilled in the art and the generic principles which are shown here, in other versions be applied. Thus, it is not intended that the present Invention to the embodiment shown restrict, but it should be consistent with the largest scope of protection, which with the principles and features described herein.

To describe the features of the present invention in more detail, please refer to the 7 to 15 in conjunction with the description below.

The 7 shows a top view of a preferred embodiment of the separation device of the present invention. The separator 700 includes a polarization beam splitter 702 with a partially reflective surface 704 within the polarization beam splitter 702 is included. Although the polarization beam splitter 702 As a cube-type beam splitter is shown in this and other figures, one of ordinary skill in the art will appreciate that other types of polarization beam splitters could be used without departing from the scope of the present invention. Either the surface reflects 704 plane polarized light rays or lets them through, depending on whether the direction of polarization is parallel to the surface 704 is or is contained within the plane of incidence of the rays. The well known terms s-polarization and p-polarization are used to refer to these two types of polarization, respectively.

The polarization beam splitter 702 further comprises a pair of optical fibers 706 and 708 which are arranged side by side such that they are parallel to each other and to one side of the beam splitter 702 are arranged. The fibers 706 and 708 each comprise a first input and a first output fiber. In a similar way are the fibers 710 and 712 a second pair of optical fibers disposed side by side such that they are parallel to each other and to a second side of the beam splitter 702 are arranged. The fibers 710 and 712 each comprise a second input and a second output fiber. The input fiber 710 need not be present in simple applications of the separator. The faces of all fibers 706 to 712 are just polished, and these polished surfaces are in the direction of the polarization beam splitter 702 arranged.

A first lens 714 and a second lens 716 are each adjacent to the end surfaces of the pair of fibers 706 and 708 and the pair of fibers 710 and 712 arranged such that each lens between its adjacently disposed fibers and the polarization beam splitter 702 and the distance between each lens and the adjacent pair of fibers is the focal length f of the lens. A first birefringent wedge plate 718 and a second birefringent wedge plate 720 are between the polarization beam splitter and the lenses, respectively 714 and 716 arranged. Likewise, a first non-linear interferometer 722 and a second non-linear interferometer 724 adjacent to the polarization beam splitter 702 disposed along the sides thereof, which are respectively opposite to the pair of fibers 706 and 708 and the pair of fibers 710 and 712 are. As will be described in greater detail below, each of the non-linear interferometers 722 and 724 by a small angle relative to the planes perpendicular to each of the common axis of the pair of fibers 706 and 708 and the common axis of the pair of fibers 710 and 712 inclined. The values of these angles are through the light paths through the separator 700 determined as described in greater detail below.

The first nonlinear interferometer 722 and the second nonlinear interferometer 724 are identical to one another and are two examples of an invention disclosed in the aforementioned co-pending U.S. Patent Application No. 09 / 247,253. The 8th illustrates a first preferred embodiment of an interferometer, which is described in this patent application. The interferometer 800 includes two parallel glass plates 880A and 880B with a room or a cavity 810 between these. The surface of the glass plate 880B on the inside is with a layer of a reflected coating 820 coated with a reflectivity of preferably 100 percent. The surface of the glass plate 880A on the inside is with a layer of a reflective coating 840 coated with a reflectivity of preferably approximately 18 percent. A λ / 4 plate 895 is inside the room 810 arranged, and a λ / 8 plate 890 is adjacent to the plate 880A and outside the room 810 arranged.

If the signal 30 into the interferometer 800 enters, it passes through the 18 percent reflective coating 840 and a waveplate (phase plate) 895 preferably with λ / 4. The λ / 4 plate 895 conducts a 180 ° round phase change between an o ray and an e ray of the signal inside the cavity 810 one, and the external λ / 8 plate 890 initiates the orbital phase change of 90 ° between the o-beam and the e-beam. The Waveplate 890 , preferably with λ / 8, finely tunes the shape of the signal 30 ,

Returning to the 7 Both work with non-linear interferometers 722 and 724 as 100% reflectors for incident light rays. In addition, both have non-linear interferometers 722 and 724 the additional property that when the light beam reflected therefrom is an optical signal composed of a plurality of channels arranged at a uniform pitch in wavelength, and the light of each channel is plane-polarized is, then the light from each second signal is reflected with a 90 ° rotation of its polarization plane direction, while the light from each remaining channel is reflected with an unchanged polarization.

In The following discussion focuses on the channels whose rays of light Rotation of the polarization plane of 90 ° experienced, arbitrarily as the straight channels The remaining channels are referred to as the odd channels taken. The use of such terminology, that is "straight Channels "or" odd Channels "in this document will only be for relief chosen the reader and means no limitation of the present invention to any particular wavelength distribution the optical channels, on the provision of intervals between the wavelengths or on the enumeration scheme. An adaptation of the present invention for use with any of numerous configurations of optical channels or systems will be understood by one of ordinary skill in the art and is within the scope and spirit of the present invention. Furthermore, it will be understood by one of ordinary skill in the art that the non-linear interferometer comprising this invention as well executed in such a way can be that it is the polarization planes of the light rays of the "odd Channels "turns, instead those of the light beams of the "straight channels", without the scope of protection and to depart from the spirit of the present invention. Such modifications are easily carried out, for example, by set the properties of the non-linear interferometer are within the scope and spirit of the invention of the present invention.

The operation of the separator 700 will be first with reference to the 9 and the 10 describing the paths of the light beams from the first input fiber 706 and each comprise odd and even channels through the separator 700 , These figures represent the trajectories and polarization states of the light of the signals and sub-signals representing the separator 700 traverse. In both, the 9 and the 10 , as well as in the 12 and the 13 which follow, the double-sided arrows within the circles are parallel to the polarization directions of the plane-polarized light which is polarized within the plane of the paper, and crosses within the circles represent plane-polarized light which is polarized perpendicular to the paper plane. With special reference to the 9 becomes signal light 902 an odd channel, which is from the fiber 706 is broadcast through the lens 714 aligned, and then through the first birefringent wedge 718 divided into two plane-polarized sub-signals, a less-deflected beam 904 and a more deflected beam 906 , In this example, the polarization of the beam 904 oriented in a direction perpendicular to the paper, and that of the beam 906 is aligned parallel to the left edge of the paper. The optical axes of the wedge 718 are aligned such that the light beams of the sub-signal 904 and the sub signal 906 each having an s-polarization and p-polarization with respect to the partially reflective surface 704 , Most of the s-polarized sub-signal beam 904 gets on the surface 704 reflected, so that the reflected beam 904A is produced. Similarly, most of the p-polarized sub-signal beam becomes 906 through the surface 704 passed through, so that the transmitted beam 906A is produced. If the polarization division of the polarization beam splitter 702 would be perfect, then the sub signal 904A 100 percent of the intensity of the subsignal 904 include, and the sub signal 906A would be 100 percent of the intensity of the sub signal 906 include. Because the polarization beam splitter 702 usually, however, will not be perfect, there is a small area, sub signal 904B , the sub signal 904 passing through the surface 704 is passed through, and another small one Area, sub signal 906B , the sub signal 906 , which at the surface 704 is reflected. Thus, there are two transmitted subsignals, 904B and 906A , and two reflected sub-signals 904A and 906B ,

Like in the 9 is shown, the two transmitted subsignals move 904B and 906A through the polarization beam splitter 702 to the first non-linear interferometer 722 , The two reflected subsignals 904A and 906B move through the polarization beam splitter 702 to the second nonlinear interferometer 724 , Light rays of the sub-signals 906A and 904A , each comprising the majority of the transmitted intensity and the reflected intensity, have the desired respective p and s polarizations, which are suitable for the operation of a perfect polarization beam splitter. Conversely, the light rays of weaker intensity of the sub signals 904B and 906B each unwanted s and p polarizations, which from the imperfect property of the beam splitter 702 come.

Both non-linear interferometers 722 and 724 reflect 100 percent of the signal light entering it. Therefore, after interacting with one or the other of the non-linear interferometers, each of the sub-signals proceeds 904A . 904B . 906A and 906B along his return or reversal path. The first nonlinear interferometer 722 and the second nonlinear interferometer 724 are aligned such that their reflective surfaces are each perpendicular to the subsignals 906A and 904A are. Therefore, the subsignals become 906A and 904A both reflected back 180 ° so that their return paths trace their respective forward paths. Because these subsignals 906A and 904A are of one wavelength of an odd channel, there is no rotation of the plane of polarization of the light beams of either one in the reflection at its respective interferometer 722 or 724 , Thus, the light beams keep the sub-signals 906A and 904A after reflection their respective property of the p and s polarization. Because the light rays of the return region of the sub signal 906A with respect to the polarization beam splitter 702 p-polarized, becomes a new sub-signal 906C , which is composed of p-polarized light and a large part of the intensity of the sub-signal 906A encompasses, through the reflective surface 704 passed through. In a similar manner, because the light beams of the return portion of the sub signal 904A with respect to the polarization beam splitter 702 s-polarized, a new sub signal 904C , which is composed of s-polarized light and a large part of the intensity of the sub-signal 904A includes, on the surface 704 reflected.

Both subsignals 904C and 906C pursue, in the opposite direction, respectively, the original paths of the sub-signals 904 and 906 back and thus become the first birefringent wedge 718 and steered through it. After passing through the first birefringent wedge 718 follow the subsignals 904C and 906C the same path back as each of the sub-signals 904 and 906 but in the opposite direction. Furthermore, the subsignals 904C and 906C the same directions of the polarization plane as the sub-signals 904 and 906 on. Thus, the two subsignals become 904C and 906C passing through the birefringent wedge 718 reunited so that they receive the output signal (output signal) 908 produce. The signal 908 tracks the original trajectory of the incoming or propagating portion of the signal 902 back and is thus through the lens 714 passed through and focused by this. The output fiber 708 is aligned so that the focused signal 908 through the output fiber 708 is captured. In this way, most of the intensity of the odd channel signal coming from the input fiber 706 radiates through the output fiber 708 collected.

The subsignals 904B and 906B include a small range of signal light intensity. Because the subsignals 904B and 906B themselves with small deflection angles respectively relative to the subsignals 906A and 904A spread, and because the reflective surfaces of the non-linear interferometer 722 and 724 each perpendicular to the beam paths of 906A and 904A are the return areas of the subsignals 904B and 906B not their original orbits through the polarization beam splitter 702 back. The change of the path at the return area from the original area of each of the sub signals 904B and 906B is such that none of these sub-signals pass through any of the output fibers 708 or 712 regardless of any transmission through or reflection at the plane 704 , Both subsignals 904B and 906B are thus lost from the system.

Because the polarization beam splitter 702 is not perfect, is also a small area, the sub signal 906D , the p-polarized return range of the sub-signal 906A on the surface 704 reflected, and a small area, the sub signal 904D , the s-polarized return range of the sub-signal 904A gets through the surface 704 passed through. Both, the sub signal 906D , which is composed of p-polarized light, and the sub-signal 904D , which is composed of s-polarized light, move in the direction of the second birefringent wedge plate 720 and through them. The second birefringent plate 720 is oriented so that the p-polarized and s-polarized beams propagate through each other as less deflected and deflected beams. Thus, the subsignals progress 906D and 904D each through the second birefringent wedge plate 720 as a less deflected beam and as a more deflected beam. Like in the 9 is shown, these beam paths are such that neither the sub-signal 906D still the sub signal 904D in the fiber 712 entry. In this way, as well as by the elimination of the sub-signals 904B and 906B , are signals of odd channels coming from the input fiber 706 be emitted, completely prevented from entering the output fiber 712 enter.

The operation of the separator 700 will now be related to the 10 for straight channels coming from the first input fiber 706 be initiated, discussed. signal light 1002 a straight channel, which from the fiber 706 is broadcast through the lens 714 aligned and then into two linearly polarized subsignals, a less deflected beam 1004 and a more deflected beam 1006 , through the first birefringent wedge 718 divided. The optical axes of the wedge 718 are aligned so that the light of the sub signal 1004 and the sub signal 1006 each having an s-polarization and a p-polarization with respect to the partially reflective surface 704 , In this example, the polarization of the beam 1004 oriented in a direction perpendicular to the plane of the paper, and that of the beam 1006 is aligned parallel to the left edge of the paper. Most of the s-polarized sub-signal beam 1004 gets on the surface 704 reflected, so that the reflected beam 1004A is produced. Similarly, most of the p-polarized sub-signal beam becomes 1006 through the surface 704 passed through, so that the transmitted beam 1006A is produced. As discussed above, there is also a small area, the sub signal 1004B , the sub signal 1004 passing through the surface 704 is passed through, and another small area, the sub signal 1006B , the sub signal 1006 , which at the surface 704 is reflected. Thus, there are two transmitted subsignals, 1004B and 1006A , and two reflected sub-signals 1004A and 1006B ,

Like in the 10 is shown, the two transmitted subsignals move 1004B and 1006A through the polarization beam splitter 702 to the first non-linear interferometer 722 , The two reflected subsignals 1004A and 1006B move through the polarization beam splitter 702 to the second nonlinear interferometer 724 , The light rays of the subsignals 1006A and 1004A , each comprising the majority of the transmitted intensity and the reflected intensity, have the desired respective p and s polarizations, which are suitable for the operation of a perfect polarization beam splitter. Conversely, the light rays of the sub signals 1004B and 1006B with the weaker intensities, respectively, the unwanted s and p polarizations resulting from the non-perfect property of the beam splitter 702 originate.

Both non-linear interferometers 722 and 724 reflect 100 percent of the signal light entering it. After interacting with one or the other of the non-linear interferometers, therefore, each of the sub-signals propagates 1004A . 1004B . 1006A and 1006B along its return or reversal route. The first nonlinear interferometer 722 and the second nonlinear interferometer 724 are aligned such that their respective reflective surfaces are each perpendicular to the subsignals 1006A and 1004A are. Therefore, the subsignals become 1006A and 1004A both reflect back 180 ° so that their return paths trace their respective forward paths. Because these subsignals 1006A and 1004A consist of a wavelength of straight channels, each undergoes a 90 ° rotation of the polarization plane in the reflection at its respective interferometer 722 or 724 , Thus, the light of the sub signals 1006A and 1004A after reflection, an s and p polarization property, respectively. Because the light of the return range of the sub signal 1006A with respect to the polarization beam splitter 702 s-polarized, becomes a new sub signal 1006d , which is composed of s-polarized light and a large part of the intensity of the sub-signal 1006A has, on the surface 704 reflected. In a similar way, because the light of the return range of the sub signal 1004A with respect to the polarization beam splitter 702 p-polarized, becomes a new sub-signal 1004D , which is composed of p-polarized light and a large part of the intensity of the sub-signal 1004A includes, through the surface 704 passed through. Both subsignals 1004D and 1006d thus become the second birefringent wedge plate 720 and passed through them. The second birefringent plate 720 is oriented in such a way that the p-polarized and s-polarized rays propagate through them in each case as less deflected and more deflected rays. The beam paths of the subsignals 1004D and 1006d are such that these two sub-signals are again combined to produce the output signal 1008 produce. The signal 1008 is through the lens 716 passed through and focused by this. The output fiber 712 is aligned so that the focused signal 1008 through the output fiber 712 is captured. In this way, most of the intensity of the signals of straight channels, that of the input fiber 706 radiate through the output fiber 712 on captured.

The subsignals 1004B and 1006B include a small range of signal light intensity. Because the subsignals 1004B and 1006B each with small deflection angles relative to the subsignals 1006A and 1004A propagate, and because the reflective surfaces of non-linear interferometers 722 and 724 each perpendicular to the beam paths of 1006A and 1004A are the return areas of the subsignals 1004B and 1006B not their original paths through the polarization beam splitter 702 back. The change in the path of the return area from the original area of each of the subsignals 1004B and 1006B is such that none of these sub-signals pass through either the output fiber 708 or 712 regardless of any passage through or reflection at the plane 704 , Both subsignals 1004B and 1006B are thus lost out of the system. Further, because of the polarization beam splitter 702 not perfect, a small area, the sub signal 1006C , the s-polarized return range of the sub-signal 1006A through the surface 704 passed through, and a small area, the sub signal 1004C , the p-polarized return range of the sub-signal 1004A gets on the surface 704 reflected. Both, the sub signal 1006C which is composed of s-polarized light and the sub-signal 1004C , which is composed of p-polarized light, move in the direction of the first birefringent wedge plate 718 and through them. The orientation of the wedge plate 718 is such that the p-polarized and s-polarized propagate through them each as more deflected and less deflected rays. Thus, the subsignals plant 1004C and 1006C through the first birefringent wedge plate 718 each as a more deflected beam and as a less deflected beam. Like in the 10 is shown, the beam paths are such that neither the sub-signal 1004C still the sub signal 1006C in the fiber 708 enters. In this way, as well as by the elimination of the sub signal 1004B and 1006B , are signals of even channels coming from the input fiber 706 radiate, completely prevented from entering the output fiber 708 to enter.

The 11 FIG. 11 is a flow chart illustrating a preferred embodiment of a method of separating an optical signal in accordance with the present invention. First, the optical signal is divided into a plurality of plane-polarized subsignals, in step 1110 , Thereafter, the plurality of plane-polarized subsignals are directed based on their respective polarities, in step 1120 , Then they are reflected, in step 1130 , The reflected sub-signals are then combined, in step 1140 ,

The operation of the separator 700 which uses the method that in the 11 will now be described with reference to the 12 and 13 describing the paths of the light beams coming from the second input fiber 710 are initiated and each have odd and even channels through the separator 700 , With special reference to the 12 becomes signal light 1212 an odd channel, which is from the fiber 710 radiates through the lens 716 aligned / collimated and then into two plane-polarized subsignals, a less deflected beam 1024 and a more deflected beam 1026 through the second birefringent wedge 720 divided, in step 1110 , The optical axes of the wedge 720 are aligned such that the light beams of the sub-signal 1204 and the sub signal 1206 each a p-polarization and an s-polarization with respect to the partially reflective surface 704 exhibit. In this example, the polarization of the beam 1204 Aligned parallel to the lower edge of the paper, and that of the beam 1206 is aligned perpendicular to the plane of the paper. Most of the p-polarized sub-signal beam 1204 gets through the surface 704 passed through, so that the transmitted beam 1204A is produced. Similarly, most of the s-polarized sub-signal beam becomes 1206 on the surface 704 reflected, so that the reflected beam 1206A is produced. If the polarization division of the polarization beam splitter 702 would be perfect, then the sub signal 1204A 100 percent of the intensity of the subsignal 1204 include, and the sub signal 1206A would be 100 percent of the intensity of the sub signal 1206 include. Because, however, the polarization beam splitter 702 In general, it will not be perfect, there is a small area, the sub signal 1204B , the sub signal 1204 , which at the surface 704 is reflected, and another small area, the sub signal 1206B , the sub signal 1206 passing through the surface 704 is passed through. Thus, there are two transmitted subsignals, 1204A and 1206B , and two reflected sub-signals, 1204B and 1206A , in step 1120 ,

Like in the 12 is shown, the two transmitted subsignals move 1204A and 1206B through the polarization beam splitter 702 to the second nonlinear interferometer 724 , The two reflected subsignals, 1204B and 1206A , are at the polarization beam splitter 702 to the first non-linear interferometer 722 reflected. The light rays of the subsignals 1204A and 1206A , which comprise the majority of each of the transmitted intensity and reflected intensity, have the desired respective p and s polarizations, which are suitable for the operation of a perfect polarization beam splitter. Conversely, the light rays of the sub signals 1206B and 1204B the weaker intensity respectively uner Wanted s and p polarizations resulting from the imperfect property of the beam splitter 702 originate.

Both non-linear interferometers 722 and 724 100 percent of the signal light entering it reflects in the step 1130 , After interacting with one or the other of the non-linear interferometers, each of the sub-signals propagates 1204A . 1204B . 1206A and 1206B therefore continue along its return or reverse path. The first nonlinear interferometer 722 and the second nonlinear interferometer 724 are aligned such that their reflective surfaces are each perpendicular to the subsignals 1206A and 1204A are. Therefore, the subsignals become 1206A and 1204A both reflect back 180 ° so that their return paths trace their respective forward paths. Because these subsignals 1206A and 1204A are of the wavelength of an odd channel, there is no rotation of the plane of polarization of the beams of either of the two at the reflection at its respective interferometer 722 or 724 , Thus, the light beams keep the sub-signals 1206A and 1204A after reflection, their respective s and p polarization properties. Because the light rays of the return region of the sub signal 1206A with respect to the polarization beam splitter 702 s-polarized, becomes a new sub-signal 1206D , which is composed of s-polarized light and a large part of the intensity of the sub-signal 1206A includes, on the reflective surface 704 reflected. In a similar way, because the light of the return range of the sub signal 1204A with respect to the polarization beam splitter 702 p-polarized, becomes a new sub-signal 1204d , which is composed of p-polarized light and a large part of the intensity of the sub-signal 1204A includes, through the surface 704 passed through, in step 1140 ,

Both of the subsignals 1204d and 1206D track the original paths of the sub-signals in the opposite direction 1204 and 1206 back and thus become the second birefringent wedge 720 and passed through it. After passing through the second birefringent wedge 720 follow the subsignals 1204d and 1206D each the same paths as the subsignals 1204 and 1206 back, but in the opposite direction. In addition, the light beams of the sub signals 1204d and 1206D the same respective direction of the polarization plane as those of the sub-signals 1204 and 1206 on. Thus, both subsignals become 1204d and 1206D passing through the birefringent wedge 720 combined again so that they get the output signal 1208 produce. The output signal 1208 tracks the original orbit of the incoming or advancing portion of the signal 1202 back and is thus through the lens 716 passed through and focused by this. The output fiber 712 is aligned so that the focused signal 1208 through the output fiber 712 is captured. In this way, most of the intensity of the signal of the odd channels, that of the input fiber 710 radiates through the output fiber 712 captured.

The subsignals 1204B and 1206B include a small range of signal light intensity. Because the subsignals 1204B and 1206B each with small deflection angles relative to the subsignals 1206A and 1204A propagate, and because the reflective surfaces of non-linear interferometers 722 and 724 perpendicular to the beam paths of each 1206A and 1204A are the return areas of the subsignals 1204B and 1206B not their original paths through the polarization beam splitter 702 back. The change in the path of the return area from the original area of each of the subsignals 1204B and 1206B is such that none of these sub-signals pass through one of the output fibers 708 or 712 regardless of any passage through or reflection at the plane 704 , Both subsignals 1204B and 1206B are thus lost out of the system.

Because the polarization beam splitter 702 is not perfect, also becomes a small area, the sub signal 1206C , the s-polarized return range of the sub-signal 1206A through the surface 704 passed through, and a small area, the sub signal 1204C , the p-polarized return range of the sub-signal 1204A gets on the surface 704 reflected. Both, the sub signal 1206C which is composed of s-polarized light and the sub-signal 1204C , which is composed of p-polarized light, move toward and through the first birefringent wedge plate 718 , The first birefringent plate 718 is oriented so that the s-polarized and p-polarized rays propagate through each of them as less deflected and more deflected rays. Thus, the subsignal plant 1206C and 1204C through the first birefringent wedge plate 718 each as a less deflected beam and as a more deflected beam. Like in the 12 is shown, these beam paths are such that neither the sub-signal 1206C still the sub signal 1204C in the fiber 708 enter. In this way, as well as by the elimination of the sub-signals 1204B and 1206B , are signals of odd channels coming from the input fiber 710 radiate, completely prevented from entering the output fiber 708 enter.

The operation of the separator 700 will now be related to the 13 for straight channels which of the second input fiber is discussed 710 be initiated. signal light 1302 a straight channel, which from the fiber 710 radiates out through the lens 716 aligned (collimated) and then through the second birefringent wedge 720 into two linearly polarized subsignals, a less deflected beam 1304 and a more deflected beam 1306 , divided, in step 1110 , The optical axes of the wedge 720 are aligned such that the light beams of the sub-signal 1304 and the sub signal 1306 each a p-polarization and s-polarization with respect to the partially reflective surface 704 exhibit. In this example, the polarization of the beam 1304 Aligned parallel to the lower edge of the paper, and that of the beam 1306 is aligned perpendicular to the plane of the paper. Most of the p-polarized sub-signal beam 1304 gets through the surface 704 passed through, so that the transmitted beam 1304A is produced. Similarly, most of the s-polarized sub-signal beam becomes 1306 on the surface 704 reflected, so that the reflected beam 1306A is produced. As discussed above, there is also a small area, the sub-signal 1304B , the sub signal 1304 , which at the surface 704 is reflected, and another small area, the sub signal 1306B , the sub signal 1306 passing through the surface 704 is passed through. Thus, there are two transmitted subsignals 1304A and 1306B , and two reflected sub-signals 1306A and 1304B , in step 1120 ,

Like in the 13 is shown, the two transmitted subsignals move 1304A and 1306B through the polarization beam splitter 702 to the second nonlinear interferometer 724 , The two reflected subsignals 1306A and 1304B move through the polarization beam splitter 702 to the first non-linear interferometer 722 , The subsignals 1304A and 1306A , each comprising the majority of the transmitted intensity and reflected intensity, have the desired p and s polarizations suitable for the operation of a perfect polarization beam splitter. Conversely, the subsignals have weaker intensity 1306B and 1304B each undesirable s and p polarizations resulting from the non-perfect property of the beam splitter 702 originate.

Both non-linear interferometers 722 and 724 Reflect 100 percent of the signal light that enters this step 1130 , Therefore, after interacting with one or the other of the non-linear interferometers, each of the sub-signals propagates 1304A . 1304B . 1306A and 1306B continuing along its return or reverse route. The first nonlinear interferometer 722 and the second nonlinear interferometer 724 are aligned such that their reflective surfaces are each perpendicular to the paths of the sub-signals 1306A and 1304A are. Therefore, the subsignals become 1306A and 1304A both reflected back 180 ° so that their return paths trace their respective forward paths. Because these subsignals 1306A and 1304A consist of a wavelength of even channels, each undergoes a rotation of the plane of polarization of 90 ° in the reflection at its respective interferometer 722 or 724 , Thus, the light of the sub signal points 1306A and 1304A after reflection, the desired p and s polarization properties, respectively. Because the light of the return range of the sub signal 1306A p-polarized with respect to the polarization beam splitter 702 is, becomes a new sub signal 1306C , which is composed of p-polarized light and a large part of the intensity of the sub-signal 1306A includes, through the surface 704 passed through. Similarly, because the light of the return range of the sub signal 1304A with respect to the polarization beam splitter 702 s-polarized, becomes a new sub signal 1304C , which is composed of s-polarized light and a large part of the intensity of the sub-signal 1304A includes, on the surface 704 reflected. Both subsignals 1306C and 1304C thus become the and through the first birefringent wedge plate 718 directed. The first birefringent plate 718 is oriented so that the p-polarized and s-polarized rays each propagate through them as more deflected and less deflected rays. Thus, the sub signal is planted 1304C and the sub signal 1306C when passing through the first birefringent wedge plate 718 each as a less deflected beam and as a more deflected beam. The beam paths of the sub signals 1304C and 1306C are such that these two sub-signals are combined again so that they output the signal 1308 produce. The signal 1308 is through the lens 714 passed through and focused by them. The output fiber 708 is aligned so that the focused signal 1308 through the output fiber 708 is captured. In this way, most of the intensity of the signals of the straight channels, that of the input fiber 710 radiate through the output fiber 708 captured, in step 1140 ,

The subsignals 1304B and 1306B comprise a small part of the signal light intensity. Because the subsignals 1304B and 1306B each with small deflection angles relative to the subsignals 1306A and 1304A propagate, and because the reflective surfaces of non-linear interferometers 722 and 724 each perpendicular to the beam paths of 1306A and 1304A are the return areas of the subsignals 1304B and 1306B not their original paths through the polarization beam splitter 702 back. The change in the path of the return area compared to the original range of each of the sub-signals 1304B and 1306B is such that none of these sub-signals pass through one of the output fibers 708 or 712 regardless of any passage through or reflection at the plane 704 , Both subsignals 1304B and 1306B are thus lost out of the system. Further, because of the polarization beam splitter 702 is not perfect, a small area becomes the sub signal 1306D , the p-polarized return range of the sub-signal 1306A on the surface 704 reflected, and a small area, the sub signal 1304D , the s-polarized return range of the sub-signal 1304A gets through the surface 704 passed. Both, the sub signal 1306D , which is composed of p-polarized light, and the sub-signal 1304D , which is composed of s-polarized light, move toward and through the second birefringent wedge plate 720 , The orientation of the wedge plate 720 is such that the p-polarized and s-polarized rays propagate through each of them as less deflected and more deflected rays. Thus, the subsignals plant 1304D and 1306D through the first birefringent wedge plate 718 each as a more deflected beam and as a less deflected beam. Like in the 13 is shown, these beam paths are such that neither the sub-signal 1304D still the sub signal 1306D in the fiber 712 entry. In this way, as well as by the elimination of subsignals 1304B and 1306B , signals of the even channels, which are from the input fiber 710 radiate, completely prevented from entering the output fiber 712 enter.

The 14 summarizes the results of the operation of the separator 700 together. The input 1402 is the signal coming from the first input fiber 706 is initiated, and the input 1404 is the signal coming from the optional second input fiber 710 if there is such a thing is initiated. The edition 1406 is the signal leading to the first output fiber 708 is issued, and the issue 1408 is the signal to the second output fiber 712 is delivered. As discussed above, signals from odd channels and even channels leading to the separator 700 from the signal 1402 of the first input, respectively to the first output fiber 708 as an output signal 1406 and to the second output fiber 712 as an output signal 1408 directed. Because the discussion of the operation of the separator 700 which is the second input signal 1404 used is identical to the one above for the operation, which is the first input signal 1402 is given, a similar relationship exists in this case. This means that the signals of odd channels and even channels, that of the second input signal 1404 to the separator 700 are input, respectively to the second output fiber 712 as an issue 1408 and to the first output fiber 708 as an issue 1406 be directed. In this way, the separator works 700 where they are either the input signal 1402 or the input signal 1404 is used as a dense wavelength division multiplexer or demultiplexer which distinguishes between the paths of odd and even channels. Because the separation of odd and even channels in the separator 700 based on an interferometric technique, the spacing between the channels in frequency is strictly periodic and thus conforms to standardized channel spacing schemes, such as those recommended by the International Telecommunication Union.

The separator 700 The present invention has the advantage of higher tolerance to drift relative to the separators of conventional wavelength division multiplexers because of the increase in the widths of the passbands provided by the non-linear interferometers included therein. It offers the further advantage of greater separation efficiency between the sets of separate channels relative to dense wavelength division separators and multiplexers using polarization beam splitters. This latter advantage occurs because the extent of physical separation of the sub-signal beams from differing polarization states through the birefringent wedge plates 718 and 720 and not by the polarization beam splitter 702 is limited. The efficiency of separating a non-polarized light beam into a first light beam comprising a first direction of plane polarization and a second light beam comprising a second direction of plane polarization perpendicular to the first is greater in a birefringent plate than in a polarization beam splitter. In the separator 700 According to the present invention, the birefringent wedges cause the signals to be separated into separate sub-signals, which comprise mutually polarized light beams. The polarization beam splitter 702 is used to represent each of these separate sub-signals, such as the sub-signal 904 and 906 , directs to another non-linear interferometer. Because of the geometry of the device 700 is any "leakage" of subsignals, which through the polarization beam splitter 702 is caused - that is, the reflection of a subsignal at the level 704 which is nominally passing straight through it, or just passing a sub signal through the plane 704 , which is nominally reflected at this - eliminated. Thus, the separator of the present invention provides greater isolation efficiency relative to other separation apparatus and wavelength division multiplexers using polarization beam splitters, from one set of separate channels to another.

Another added functionality and another advantage of the separator 700 The ability of the present invention to perform the add / drop function while also separating the channels. Like in the 14 is shown, two signals, a first input signal 1402 , which includes the channel signals λ ₁ - λ _n , and a second input signal 1404 which includes channel signals λ ₁ '- λ _n ', both into the separator 700 initiated. The separator 700 may then remove the even channels from the first signal to the second signal while adding the even channels of the second signal to the first signal. For example, as in the 14 is shown, would be the first output signal 1406 from the odd channels (λ ₁ , λ ₃ , λ ₅ ...) from the first input signal 1402 plus the even channels (λ ₂ ', λ ₄ ', λ ₆ '...) of the second input signal 1404 consist. In the same way would the second output signal 1408 from the odd channels (λ ₁ ', λ ₃ ', λ ₅ '...) from the second input signal 1404 plus the even channels (λ ₂ , λ ₄ , λ ₆ ...) from the first input signal 1402 consist.

Another advantage of the separator 700 The ability of the present invention to position them within a multi-stage parallel cascade configuration to reduce insertion loss as part of a larger dense wavelength multiplexer. This configuration is in the 15 and is disclosed in co-pending U.S. Patent Application entitled "Fiber Optic Dense Wavelength Division Multiplexer Utilizing a Multi-Stage Parallel Cascade Method of Wavelength Separation", Application Number 09 / 130,386, filed August 6, 1998 15 An optical signal including the channels λ ₁ -λ _n enters the dense wavelength multiplexer 1500 of the present invention by the node A 240 one. The signal passes through a separator 1510A of the present invention. The separator 1510A divides the signal into two separate signals, one containing the odd channels (λ ₁ , λ ₃ , λ ₅ ...), and the other the even channels (λ ₂ , λ ₄ , λ ₆ ...) ( 1540 ) as described above. These odd and even channels are then each separated by another separator 1510B and 1510C passed through, which further subdivides this with each other channel. The separator 1510B and in particular the set of non-linear interferometers comprising this separator is modified to include the set of channels λ ₁ , λ ₅ , λ ₉ ... from the set of channels λ ₃ , λ ₇ , λ ₁₁ ... by adjusting the wavelength spacing of the channels whose polarization directions are rotated. In a similar way is the separator 1510C and in particular, the set of non-linear interferometers comprising this separation device is modified to include the set of channels λ ₂ , λ ₆ , λ ₁₀ ... from the set of channels λ ₄ , λ ₈ , λ ₁₂ . .. by a similar setting. A similar channel split is continued until only one channel to each optical fiber 250-1 to 250-n is issued. In a dense wavelength division multiplexer constructed according to the multi-stage parallel cascade configuration of the present invention, there is no reduction in the widths of the passbands relative to those of the channel separator 1510A in the first stage. This is in contrast to and an advantage over conventional filter technologies, which, when chained together in a row as part of a larger optical device, cause a reduction in the overall passband width of the filter assemblage relative to a single filter. The present invention is thus free of increased insertion losses associated with such reduced passband widths. Although the separator of the present invention has been described as being used in the multi-stage parallel cascade configuration of the present invention, one of ordinary skill in the art will appreciate that the separator of the present invention may be used in other configurations without departing from the scope of the present invention.

One improved separation mechanism, which in a multiplexer dense wavelength (DWDM) has been used has been disclosed. The separator The present invention includes a mechanism of inputting an optical signal, wherein the optical signal of a plurality of optical channels consists; a mechanism of separating one or more the variety of optical channels by introducing a phase difference between at least two of the channels of the optical signal; and a mechanism of outputting the separated plurality of channels along a variety of optical paths. The mechanism of Separating one or more of the plurality of optical channels includes birefringent ones Beam separation and recombination plates, a polarization beam splitter and two non-linear interferometers, with the birefringent ones Plates between the polarization beam splitter and the input and output paths are arranged, and the two non-linear interferometers on opposite sides of the polarization beam splitter of the input and output paths are arranged.

The present invention provides ease of alignment and a higher one Tolerance Drifting due to enlargement in the widths of the passbases available and provides as well improved separation of channels relative to other wavelength division multiplexers, which polarization beam splitters use. she can easily be modified to do the add / drop function executing, when she separates the channels. The materials required to make the multiplexer more dense wavelength in accordance to produce and implement with the present invention, are readily available. The present invention thus requires no special or expensive materials or processes. It is thus inexpensive.

Even though the present invention in accordance with the shown versions the person of ordinary skill in the art will readily recognize that there are variations on the designs can give, and accordingly, many modifications through the person skilled in the art without departing from the scope of the appended claims.

Claims (7)

A dense wavelength multiplexer ( 700 ) for separating an optical signal into optical channels, comprising: at least one of a first optical fiber ( 706 . 710 ) for introducing an optical signal, the optical signal comprising a plurality of optical channels; at least one of a first lens ( 714 ), which optically to the first optical fiber ( 706 . 710 ) is coupled; at least two of a second optical fiber ( 708 . 712 ) for outputting one or more optical channels, wherein at least one ( 708 ) of the second optical fibers optically to the first lens ( 714 ) is coupled; at least one of a second lens ( 716 ), which optically to the second optical fibers ( 712 ) which is not optically coupled to the first lens ( 714 ) are coupled; a polarization beam splitter ( 702 ) with four connections; a first birefringent wedge plate ( 718 ), which optically between the first terminal of the polarization beam splitter ( 702 ) and the first lens ( 714 ) is coupled; a second birefringent part plate ( 720 ), which optically between the second terminal of the polarization beam splitter ( 702 ) and the second lens ( 716 ) is coupled; and at least two non-linear interferometers ( 722 . 724 ), which optically to the third and the fourth terminal of the polarization beam splitter ( 702 ) are coupled on opposite sides of the polarization beam splitter to the first and the second optical fibers, the polarization beam splitter ( 702 ) for directing polarized subsignals of the optical signal to one of the at least two non-linear interferometers ( 722 . 724 ) based on their polarity, and wherein each non-linear interferometer ( 722 . 724 ) the or each guided sub-signal in the direction of the respective second optical fiber ( 708 . 712 ) opposite to this reflected; wherein each of the non-linear interferometers ( 722 . 724 ) comprises: a first glass plate ( 880A ), which optically to a second glass plate ( 880B ) is coupled so that a cavity ( 810 ) is formed; a first reflective coating ( 820 ), which within the cavity ( 810 ) and on the second glass plate ( 880B ) is arranged; a second reflective coating ( 840 ), which within the cavity ( 810 ) and on the first glass plate ( 880A ) is arranged; a first waveplate ( 895 ), which within the cavity ( 810 ) between the first ( 880A ) and the second ( 880B ) Glass plate is arranged; and a second waveplate ( 890 ), which outside the cavity ( 810 ) is arranged. A dense wavelength division multiplexer as claimed in claim 1, wherein the first reflective coating ( 820 ) comprises a reflective coating with a reflectivity of 100 percent. A dense wavelength division multiplexer as claimed in claim 1 or claim 2, wherein the second reflective coating ( 840 ) comprises a reflective coating having a reflectivity of approximately 18 percent. A dense wavelength division multiplexer as claimed in any of claims 1, 2 or 3, wherein the first waveplate ( 895 ) comprises a λ / 4 waveplate. A dense wavelength division multiplexer as claimed in any of claims 1, 2, 3 or 4, wherein the second waveplate ( 890 ) comprises a λ / 8 waveplate. A method of separating an optical signal into optical channels, comprising the steps of: (a) dividing the optical signal by means of a first birefringent wedge plate ( 718 ) into a plurality of plane-polarized subsignals; (b) directing each of the plurality of plane-polarized subsignals based on their polarity by means of a polarization beam splitter ( 702 ); (c) reflecting the plurality of routed ebe nary polarized subsignals through a plurality of nonlinear interferometers ( 722 . 724 ); and (d) combining at least two of the plurality of guided and reflected planar polarized subsignals with a second birefringent wedge plate (US Pat. 720 ); wherein each of the non-linear interferometers ( 722 . 724 ) comprises: a first glass plate ( 880A ), which optically to a second glass plate ( 880B ) is coupled so that a cavity ( 810 ) is formed; a first reflective coating ( 820 ), which within the cavity ( 810 ) and on the second glass plate ( 880B ) is arranged; a second reflective coating ( 840 ), which within the cavity ( 810 ) and on the first glass plate ( 880A ) is arranged; a first waveplate ( 895 ), which within the cavity ( 810 ) between the first ( 880A ) and the second ( 880B ) Glass plate is arranged; and a second waveplate ( 890 ), which outside the cavity ( 810 ) is arranged. A system for separating an optical signal into optical channels, comprising: a plurality of optical fibers ( 706 . 708 . 710 . 712 ) for carrying the optical signal or a part thereof; and a dense wavelength multiplexer ( 700 ), comprising a plurality of separation devices at least partially in a multi-stage parallel cascade configuration, each separation device comprising: a first lens (10); 714 ), which visually to at least a first birefringent wedge plate ( 718 ) is coupled to receive the optical signal; and a polarization beam splitter ( 702 ), which via a first connection optically to the at least one first birefringent wedge plate ( 718 ), the polarization beam splitter ( 702 ) and the at least one first birefringent wedge plate ( 718 ) for separating one or more of the plurality of optical channels by introducing a phase difference between at least two of the plurality of optical channels, wherein the separating is based on the polarity of the plurality of optical channels; and at least one second birefringent wedge plate ( 720 ), which optically between another terminal of the polarization beam splitter and a second lens ( 716 ) is coupled; and at least two non-linear interferometers ( 722 . 724 ), which optically to a third and a fourth terminal of the polarization beam splitter ( 702 ), and disposed on opposite sides of the polarization beam splitter opposite the first and second lenses and birefringent wedge plates, the polarization beam splitter for directing polarized subsignals of the optical signal to one of the at least two non-linear interferometers based on their polarity, and each non-linear interferometers reflect the or each guided sub-signal in the direction of the respective lens and birefringent wedge plate opposite thereto; wherein each of the non-linear interferometers ( 722 . 724 ) comprises: a first glass plate ( 880A ), which optically to a second glass plate ( 880B ) is coupled so that a cavity ( 810 ) is formed; a first reflective coating ( 820 ), which within the cavity ( 810 ) and on the second glass plate ( 880B ) is arranged; a second reflective coating ( 840 ), which within the cavity ( 810 ) and on the first glass plate ( 880A ) is arranged; a first waveplate ( 895 ), which within the cavity ( 810 ) between the first ( 880A ) and the second ( 880B ) Glass plate is arranged; and a second waveplate ( 890 ), which outside the cavity ( 810 ) is arranged.